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Aquatic Ecology
Aquatic Ecology And
The Food Web
ome Understanding of the aquatic ecosystem Ponds and lakes go through a cycle of changes over
is necessary before fi sheries managers or pond time, from newly created aquatic environment back
Sowners can begin to understand changes in fi sh to terrestrial habitat.
populations. The aquatic ecosystem is a complex of
interrelated species and their reaction to each other New ponds and lakes are usually oligothrophic.
and their habitat. Oligotrophic waters have very little nutrients, a small
phytoplankton population and consequently, clear
Changes in one part of the system often cause water unless it is colored by dissolved or suspended
changes, large and small, throughout the system. minerals.
Eradication of aquatic plants in a pond with a healthy As the pond ages, leaves and other material wash into
largemouth bass population is a good example of it from the watershed and plants and animals die and
this concept. When all plants are eliminated from decay; gradually increasing the amount of nutrients
the pond in an effort to improve angling access; available to the ecosystem. The phytoplankton
forage fi sh such as bluegill lose their protective community increases and the water becomes less
cover and are exposed to excessive predation by clear and more green. Vascular aquatic plants
largemouth bass. Bass initially respond by growing colonize the shoreline and extend into the water as
and reproducing rapidly, however, as the forage nutrients become available. Lakes with high levels
fi sh population declines, the once healthy bass of nutrients are said to be eutrophic. The pond has
population, limited by declining food supplies, reached a mature stage of development.
becomes numerous, small and stunted.
Highly eutrophic or polluted lakes can result from
The basic ecological concepts discussed in this activities in the watershed that release plant nutrients.
section will provide the pond owner with the Farm fertilizers, livestock manure, some detergents
knowledge necessary to understand the reasoning or other waste material containing nitrogen or
behind fi sh and plant management techniques. phosphorous washing into the water produce
noxious algae blooms and excessive phytoplankton
Succession production that is characteristic of this condition.
The aquatic ecosystem is a dynamic, changing Over time, leaves, dead plants and animals and other
environment. Daily and annual bio-geo-chemical detritus accumulates on the pond bottom. The pond
cycles drive changes in water chemistry and the becomes progressively shallower to the point that
species composition of aquatic communities. light penetrates all areas of the pond bottom and
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Aquatic Ecology
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Aquatic Ecology
aquatic vegetation covers the waters surface. The ecosystems phytoplankton are the primary producers;
pond has reached the age of senescence. other aquatic plants also contribute but to a lesser
Willows, cypress, cattail and other shoreline plants extent. The total amount of energy per unit of time
advance toward the ponds center. fi xed as plant tissue is called primary production.
Plants are able to convert only about 1-2 percent of
Eventually rooted plants cover the pond bottom the available sunlight energy into chemical energy
and the pond becomes a bog or marsh. Dry land usable for plant production.
trees begin to invade areas that were once under
water. The marsh eventually fi lls in and drys up. Each time energy passes from one trophic level
Surrounding terrestrial vegetation replaces aquatic to the next, for example, a grass carp eating an
and semi-aquatic plant species and succession is aquatic plant or a largemouth bass consuming a
complete. This successional cycle can be disrupted bluegill, about 90 percent of the energy will be lost.
at any time by natural events such as fl oods that Consequently, ecosystems require a large base of
can scour, deepen and rejuvenate the pond. Human primary production to support a relatively modest
activity such as draining and dredging the pond also level of production at higher trophic levels. The
can interrupt the successional cycle. Eltonian trophic pyramid shown in fi g, 2 illustrates
this concept graphically.
Energy movement in the aquatic Light is needed for all plant growth. Because clear
ecosystem ponds allow light penetration to greater depths than
An ecosystem can be thought of as a conduit of muddy ponds, more phytoplankton and other plants
energy derived from sunlight. Energy from the sun can grow, resulting in greater primary production in
plus inorganic materials are the basis of all life. the base of the food chain.
Energy can not be recycled. It moves through the More production in the food web base allows more
ecosystem and ultimately dissipates as heat. Energy production through out the aquatic ecosystem; and
transfer effi ciencies are low, usually about 10 % consequently, greater natural fi sh production in clear
between each trophic level of the ecosystem. ponds than in muddy ponds.
Trophic levels contain groups of organisms with Fish production in muddy ponds can be increased by
similar methods of food (energy)consumption. clearing the pond or by addition of supplemental fi sh
Energy moves from one trophic level to the next food to compensate for lack of primary production.
through the food web fi g. 1. An example of a
common, linear aquatic food chain is: Fish production in clear ponds can be increased
Phytoplankton (microscopic
plants) - Zooplankton (microscopic
animals) -Insects - Blue gill -
Largemouth Bass -Turtle -Bacteria
In reality, most food chains are
usually complex and interconnected.
They are more accurately described
as food webs.
Producers are the fi rst trophic level
in the ecosytem and form the base
of the food chain. Producers obtain
nutrition from inorganic materials
and sunlight energy. In aquatic
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Aquatic Ecology
by the addition of plant fertilizers to stimulate habits, is represented in the example as a scavenger.
primary production. Fertilization only improves fi sh Organisms at this trophic level feed on large bits of
production if plant nutrients are lacking and light dead or decaying organic matter.
penetration is suffi cient to allow increased plant
growth. (When a specifi c factor is not available Organisms of the fi nal trophic level break down
in suffi cient quantity and restricts the growth of organic matter and animal waste products. These
organisms it is called a limiting factor. For example, creatures are called decomposers, and they break
light is a limiting factor for plant growth in muddy down organic material back to its constituent
ponds.) elements Bacteria are the most numerous and
important decomposing organisms.
In most situations, nutrients are actually over
abundant, due to livestock waste or farm fertilizers. Ecological pyramids can be constructed using
An over abundance of nutrients in clear ponds results numbers of organisms, energy consumption in the
in green, phytoplankton rich
water; or excessive growth of
rooted aquatic plants.
Consumers make up the
next trophic level; and must
eat other organisms to obtain
their energy. Consumers, in
turn, occupy different trophic
levels. Trophic levels of
common aquatic organisms
are shown in table 1.
Primary consumers are
herbivores, they eat plants.
In our aquatic ecosystem
example, zooplankton feeding
on phytoplankton occupy the
primary consumer trophic
level. Cattle are primary
consumers in terrestrial
ecosystems.
Secondary consumers,
represented by certain aquatic
insects are carnivores and
feed upon primary consumers,
the zooplankton.
Our example also includes
a tertiary consumer, the
largemouth bass that feeds
upon other carnivores.
The turtle, although
opportunistic in its feeding
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